Host and gut microbial tryptophan metabolism and type 2 diabetes: an integrative analysis of host genetics, diet, gut microbiome and circulating metabolites in cohort studies

Qibin Qi; Jun Li; Bing Yu; Jee Young Moon; Jin C. Chai; Jordi Merino; Jie Hu; Miguel Ruiz-Canela; Casey Rebholz; Zheng Wang; Mykhaylo Usyk; Guo Chong Chen; Bianca C. Porneala; Wenshuang Wang; Ngoc Quynh Nguyen; Elena V. Feofanova; Megan L. Grove; Thomas J. Wang; Robert E. Gerszten; Josée Dupuis; Jordi Salas-Salvadó; Wei Bao; David L. Perkins; Martha L. Daviglus; Bharat Thyagarajan; Jianwen Cai; Tao Wang; Jo Ann E. Manson; Miguel A. Martínez-González; Elizabeth Selvin; Kathryn M. Rexrode; Clary B. Clish; Frank B. Hu; James B. Meigs; Rob Knight; Robert D. Burk; Eric Boerwinkle; Robert C. Kaplan

doi:10.1136/gutjnl-2021-324053

Host and gut microbial tryptophan metabolism and type 2 diabetes: an integrative analysis of host genetics, diet, gut microbiome and circulating metabolites in cohort studies

Qibin Qi, Jun Li, Bing Yu, Jee Young Moon, Jin C. Chai, Jordi Merino, Jie Hu, Miguel Ruiz-Canela, Casey Rebholz, Zheng Wang, Mykhaylo Usyk, Guo Chong Chen, Bianca C. Porneala, Wenshuang Wang, Ngoc Quynh Nguyen, Elena V. Feofanova, Megan L. Grove, Thomas J. Wang, Robert E. Gerszten, Josée DupuisJordi Salas-Salvadó, Wei Bao, David L. Perkins, Martha L. Daviglus, Bharat Thyagarajan, Jianwen Cai, Tao Wang, Jo Ann E. Manson, Miguel A. Martínez-González, Elizabeth Selvin, Kathryn M. Rexrode, Clary B. Clish, Frank B. Hu, James B. Meigs, Rob Knight, Robert D. Burk, Eric Boerwinkle, Robert C. Kaplan

Research output: Contribution to journal › Article › peer-review

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Abstract

Objective Tryptophan can be catabolised to various metabolites through host kynurenine and microbial indole pathways. We aimed to examine relationships of host and microbial tryptophan metabolites with incident type 2 diabetes (T2D), host genetics, diet and gut microbiota. Method We analysed associations between circulating levels of 11 tryptophan metabolites and incident T2D in 9180 participants of diverse racial/ethnic backgrounds from five cohorts. We examined host genome-wide variants, dietary intake and gut microbiome associated with these metabolites. Results Tryptophan, four kynurenine-pathway metabolites (kynurenine, kynurenate, xanthurenate and quinolinate) and indolelactate were positively associated with T2D risk, while indolepropionate was inversely associated with T2D risk. We identified multiple host genetic variants, dietary factors, gut bacteria and their potential interplay associated with these T2D-relaetd metabolites. Intakes of fibre-rich foods, but not protein/tryptophan-rich foods, were the dietary factors most strongly associated with tryptophan metabolites. The fibre-indolepropionate association was partially explained by indolepropionate-associated gut bacteria, mostly fibre-using Firmicutes. We identified a novel association between a host functional LCT variant (determining lactase persistence) and serum indolepropionate, which might be related to a host gene-diet interaction on gut Bifidobacterium, a probiotic bacterium significantly associated with indolepropionate independent of other fibre-related bacteria. Higher milk intake was associated with higher levels of gut Bifidobacterium and serum indolepropionate only among genetically lactase non-persistent individuals. Conclusion Higher milk intake among lactase non-persistent individuals, and higher fibre intake were associated with a favourable profile of circulating tryptophan metabolites for T2D, potentially through the host-microbial cross-talk shifting tryptophan metabolism toward gut microbial indolepropionate production.

Original language	English (US)
Pages (from-to)	1095-1105
Number of pages	11
Journal	Gut
Volume	71
Issue number	6
DOIs	https://doi.org/10.1136/gutjnl-2021-324053
State	Published - Jun 1 2022

ASJC Scopus subject areas

Gastroenterology

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1136/gutjnl-2021-324053

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Qi, Q., Li, J., Yu, B., Moon, J. Y., Chai, J. C., Merino, J., Hu, J., Ruiz-Canela, M., Rebholz, C., Wang, Z., Usyk, M., Chen, G. C., Porneala, B. C., Wang, W., Nguyen, N. Q., Feofanova, E. V., Grove, M. L., Wang, T. J., Gerszten, R. E., ... Kaplan, R. C. (2022). Host and gut microbial tryptophan metabolism and type 2 diabetes: an integrative analysis of host genetics, diet, gut microbiome and circulating metabolites in cohort studies. Gut, 71(6), 1095-1105. https://doi.org/10.1136/gutjnl-2021-324053

Qi, Q, Li, J, Yu, B, Moon, JY, Chai, JC, Merino, J, Hu, J, Ruiz-Canela, M, Rebholz, C, Wang, Z, Usyk, M, Chen, GC, Porneala, BC, Wang, W, Nguyen, NQ, Feofanova, EV, Grove, ML, Wang, TJ, Gerszten, RE, Dupuis, J, Salas-Salvadó, J, Bao, W, Perkins, DL, Daviglus, ML, Thyagarajan, B, Cai, J, Wang, T, Manson, JAE, Martínez-González, MA, Selvin, E, Rexrode, KM, Clish, CB, Hu, FB, Meigs, JB, Knight, R, Burk, RD, Boerwinkle, E & Kaplan, RC 2022, 'Host and gut microbial tryptophan metabolism and type 2 diabetes: an integrative analysis of host genetics, diet, gut microbiome and circulating metabolites in cohort studies', Gut, vol. 71, no. 6, pp. 1095-1105. https://doi.org/10.1136/gutjnl-2021-324053

@article{e44b580ef56f44f2a5eb3cdda0d9599e,

title = "Host and gut microbial tryptophan metabolism and type 2 diabetes: an integrative analysis of host genetics, diet, gut microbiome and circulating metabolites in cohort studies",

abstract = "Objective Tryptophan can be catabolised to various metabolites through host kynurenine and microbial indole pathways. We aimed to examine relationships of host and microbial tryptophan metabolites with incident type 2 diabetes (T2D), host genetics, diet and gut microbiota. Method We analysed associations between circulating levels of 11 tryptophan metabolites and incident T2D in 9180 participants of diverse racial/ethnic backgrounds from five cohorts. We examined host genome-wide variants, dietary intake and gut microbiome associated with these metabolites. Results Tryptophan, four kynurenine-pathway metabolites (kynurenine, kynurenate, xanthurenate and quinolinate) and indolelactate were positively associated with T2D risk, while indolepropionate was inversely associated with T2D risk. We identified multiple host genetic variants, dietary factors, gut bacteria and their potential interplay associated with these T2D-relaetd metabolites. Intakes of fibre-rich foods, but not protein/tryptophan-rich foods, were the dietary factors most strongly associated with tryptophan metabolites. The fibre-indolepropionate association was partially explained by indolepropionate-associated gut bacteria, mostly fibre-using Firmicutes. We identified a novel association between a host functional LCT variant (determining lactase persistence) and serum indolepropionate, which might be related to a host gene-diet interaction on gut Bifidobacterium, a probiotic bacterium significantly associated with indolepropionate independent of other fibre-related bacteria. Higher milk intake was associated with higher levels of gut Bifidobacterium and serum indolepropionate only among genetically lactase non-persistent individuals. Conclusion Higher milk intake among lactase non-persistent individuals, and higher fibre intake were associated with a favourable profile of circulating tryptophan metabolites for T2D, potentially through the host-microbial cross-talk shifting tryptophan metabolism toward gut microbial indolepropionate production.",

author = "Qibin Qi and Jun Li and Bing Yu and Moon, {Jee Young} and Chai, {Jin C.} and Jordi Merino and Jie Hu and Miguel Ruiz-Canela and Casey Rebholz and Zheng Wang and Mykhaylo Usyk and Chen, {Guo Chong} and Porneala, {Bianca C.} and Wenshuang Wang and Nguyen, {Ngoc Quynh} and Feofanova, {Elena V.} and Grove, {Megan L.} and Wang, {Thomas J.} and Gerszten, {Robert E.} and Jos{\'e}e Dupuis and Jordi Salas-Salvad{\'o} and Wei Bao and Perkins, {David L.} and Daviglus, {Martha L.} and Bharat Thyagarajan and Jianwen Cai and Tao Wang and Manson, {Jo Ann E.} and Mart{\'i}nez-Gonz{\'a}lez, {Miguel A.} and Elizabeth Selvin and Rexrode, {Kathryn M.} and Clish, {Clary B.} and Hu, {Frank B.} and Meigs, {James B.} and Rob Knight and Burk, {Robert D.} and Eric Boerwinkle and Kaplan, {Robert C.}",

note = "Funding Information: This work is supported by R01-DK119268 (QQ) from the National Institute of Diabetes and Digestive and Kidney Diseases (NIDDK), R01-MD011389 (RK, RDB and RCK) from the National Institute on Minority Health and Health Disparities, and R01-HL060712 (QQ and FBH) from the National Heart, Lung and Blood Institute (NHLBI). Other funding sources for this study include UM1-HG008898 from the National Human Genome Research Institute; R01-HL140976, and R01-HL136266 from the NHLBI; and R01-DK120870, R01 DK126698 and the New York Regional Center for Diabetes Translation Research (P30DK111022) from NIDDK. Support for metabolomics data was graciously provided by the JLH Foundation (Houston, Texas). JL is supported by 9-17-CMF-011 from the American Diabetes Association (ADA); K99-DK122128 from NIDDK; and a pilot and feasibility grant from the NIDDK-funded Boston Nutrition Obesity Research Center (P30-DK046200). BY is supported by the American Heart Association (17SDG33661228); and R01-HL141824 and R01-HL142003 from NHLBI. JM and JD are supported by U01-DK078616 from NIDDK. JM is supported by a postdoctoral fellowship funded by the European Commission Horizon 2020 programme; Marie Sk{\l}odowska-Curie actions (H2020-MSCA-IF-2015-703787); and P30DK040561 from NIDDK. Funding and acknowledgment information for each participating studies is provided in online supplements. Funding Information: Funding This work is supported by R01-DK119268 (QQ) from the National Institute of Diabetes and Digestive and Kidney Diseases (NIDDK), R01-MD011389 (RK, RDB and RCK) from the National Institute on Minority Health and Health Disparities, and R01-HL060712 (QQ and FBH) from the National Heart, Lung and Blood Institute (NHLBI). Other funding sources for this study include UM1- HG008898 from the National Human Genome Research Institute; R01-HL140976, and R01-HL136266 from the NHLBI; and R01-DK120870, R01 DK126698 and the New York Regional Center for Diabetes Translation Research (P30DK111022) from NIDDK. Support for metabolomics data was graciously provided by the JLH Foundation (Houston, Texas). JL is supported by 9-17-CMF-011 from the American Diabetes Association (ADA); K99-DK122128 from NIDDK; and a pilot and feasibility grant from the NIDDK-funded Boston Nutrition Obesity Research Center (P30-DK046200). BY is supported by the American Heart Association (17SDG33661228); and R01-HL141824 and R01-HL142003 from NHLBI. JM and JD are supported by U01-DK078616 from NIDDK. JM is supported by a postdoctoral fellowship funded by the European Commission Horizon 2020 programme; Marie Sk{\l}odowska-Curie actions (H2020-MSCA-IF-2015-703787); and P30DK040561 from NIDDK. Funding and acknowledgment information for each participating studies is provided in online supplements. Publisher Copyright: {\textcopyright} Author(s) (or their employer(s)) 2022.",

year = "2022",

month = jun,

day = "1",

doi = "10.1136/gutjnl-2021-324053",

language = "English (US)",

volume = "71",

pages = "1095--1105",

journal = "Gut",

issn = "0017-5749",

publisher = "BMJ Publishing Group",

number = "6",

}

TY - JOUR

T1 - Host and gut microbial tryptophan metabolism and type 2 diabetes

T2 - an integrative analysis of host genetics, diet, gut microbiome and circulating metabolites in cohort studies

AU - Qi, Qibin

AU - Li, Jun

AU - Yu, Bing

AU - Moon, Jee Young

AU - Chai, Jin C.

AU - Merino, Jordi

AU - Hu, Jie

AU - Ruiz-Canela, Miguel

AU - Rebholz, Casey

AU - Wang, Zheng

AU - Usyk, Mykhaylo

AU - Chen, Guo Chong

AU - Porneala, Bianca C.

AU - Wang, Wenshuang

AU - Nguyen, Ngoc Quynh

AU - Feofanova, Elena V.

AU - Grove, Megan L.

AU - Wang, Thomas J.

AU - Gerszten, Robert E.

AU - Dupuis, Josée

AU - Salas-Salvadó, Jordi

AU - Bao, Wei

AU - Perkins, David L.

AU - Daviglus, Martha L.

AU - Thyagarajan, Bharat

AU - Cai, Jianwen

AU - Wang, Tao

AU - Manson, Jo Ann E.

AU - Martínez-González, Miguel A.

AU - Selvin, Elizabeth

AU - Rexrode, Kathryn M.

AU - Clish, Clary B.

AU - Hu, Frank B.

AU - Meigs, James B.

AU - Knight, Rob

AU - Burk, Robert D.

AU - Boerwinkle, Eric

AU - Kaplan, Robert C.

N1 - Funding Information: This work is supported by R01-DK119268 (QQ) from the National Institute of Diabetes and Digestive and Kidney Diseases (NIDDK), R01-MD011389 (RK, RDB and RCK) from the National Institute on Minority Health and Health Disparities, and R01-HL060712 (QQ and FBH) from the National Heart, Lung and Blood Institute (NHLBI). Other funding sources for this study include UM1-HG008898 from the National Human Genome Research Institute; R01-HL140976, and R01-HL136266 from the NHLBI; and R01-DK120870, R01 DK126698 and the New York Regional Center for Diabetes Translation Research (P30DK111022) from NIDDK. Support for metabolomics data was graciously provided by the JLH Foundation (Houston, Texas). JL is supported by 9-17-CMF-011 from the American Diabetes Association (ADA); K99-DK122128 from NIDDK; and a pilot and feasibility grant from the NIDDK-funded Boston Nutrition Obesity Research Center (P30-DK046200). BY is supported by the American Heart Association (17SDG33661228); and R01-HL141824 and R01-HL142003 from NHLBI. JM and JD are supported by U01-DK078616 from NIDDK. JM is supported by a postdoctoral fellowship funded by the European Commission Horizon 2020 programme; Marie Skłodowska-Curie actions (H2020-MSCA-IF-2015-703787); and P30DK040561 from NIDDK. Funding and acknowledgment information for each participating studies is provided in online supplements. Funding Information: Funding This work is supported by R01-DK119268 (QQ) from the National Institute of Diabetes and Digestive and Kidney Diseases (NIDDK), R01-MD011389 (RK, RDB and RCK) from the National Institute on Minority Health and Health Disparities, and R01-HL060712 (QQ and FBH) from the National Heart, Lung and Blood Institute (NHLBI). Other funding sources for this study include UM1- HG008898 from the National Human Genome Research Institute; R01-HL140976, and R01-HL136266 from the NHLBI; and R01-DK120870, R01 DK126698 and the New York Regional Center for Diabetes Translation Research (P30DK111022) from NIDDK. Support for metabolomics data was graciously provided by the JLH Foundation (Houston, Texas). JL is supported by 9-17-CMF-011 from the American Diabetes Association (ADA); K99-DK122128 from NIDDK; and a pilot and feasibility grant from the NIDDK-funded Boston Nutrition Obesity Research Center (P30-DK046200). BY is supported by the American Heart Association (17SDG33661228); and R01-HL141824 and R01-HL142003 from NHLBI. JM and JD are supported by U01-DK078616 from NIDDK. JM is supported by a postdoctoral fellowship funded by the European Commission Horizon 2020 programme; Marie Skłodowska-Curie actions (H2020-MSCA-IF-2015-703787); and P30DK040561 from NIDDK. Funding and acknowledgment information for each participating studies is provided in online supplements. Publisher Copyright: © Author(s) (or their employer(s)) 2022.

PY - 2022/6/1

Y1 - 2022/6/1

N2 - Objective Tryptophan can be catabolised to various metabolites through host kynurenine and microbial indole pathways. We aimed to examine relationships of host and microbial tryptophan metabolites with incident type 2 diabetes (T2D), host genetics, diet and gut microbiota. Method We analysed associations between circulating levels of 11 tryptophan metabolites and incident T2D in 9180 participants of diverse racial/ethnic backgrounds from five cohorts. We examined host genome-wide variants, dietary intake and gut microbiome associated with these metabolites. Results Tryptophan, four kynurenine-pathway metabolites (kynurenine, kynurenate, xanthurenate and quinolinate) and indolelactate were positively associated with T2D risk, while indolepropionate was inversely associated with T2D risk. We identified multiple host genetic variants, dietary factors, gut bacteria and their potential interplay associated with these T2D-relaetd metabolites. Intakes of fibre-rich foods, but not protein/tryptophan-rich foods, were the dietary factors most strongly associated with tryptophan metabolites. The fibre-indolepropionate association was partially explained by indolepropionate-associated gut bacteria, mostly fibre-using Firmicutes. We identified a novel association between a host functional LCT variant (determining lactase persistence) and serum indolepropionate, which might be related to a host gene-diet interaction on gut Bifidobacterium, a probiotic bacterium significantly associated with indolepropionate independent of other fibre-related bacteria. Higher milk intake was associated with higher levels of gut Bifidobacterium and serum indolepropionate only among genetically lactase non-persistent individuals. Conclusion Higher milk intake among lactase non-persistent individuals, and higher fibre intake were associated with a favourable profile of circulating tryptophan metabolites for T2D, potentially through the host-microbial cross-talk shifting tryptophan metabolism toward gut microbial indolepropionate production.

AB - Objective Tryptophan can be catabolised to various metabolites through host kynurenine and microbial indole pathways. We aimed to examine relationships of host and microbial tryptophan metabolites with incident type 2 diabetes (T2D), host genetics, diet and gut microbiota. Method We analysed associations between circulating levels of 11 tryptophan metabolites and incident T2D in 9180 participants of diverse racial/ethnic backgrounds from five cohorts. We examined host genome-wide variants, dietary intake and gut microbiome associated with these metabolites. Results Tryptophan, four kynurenine-pathway metabolites (kynurenine, kynurenate, xanthurenate and quinolinate) and indolelactate were positively associated with T2D risk, while indolepropionate was inversely associated with T2D risk. We identified multiple host genetic variants, dietary factors, gut bacteria and their potential interplay associated with these T2D-relaetd metabolites. Intakes of fibre-rich foods, but not protein/tryptophan-rich foods, were the dietary factors most strongly associated with tryptophan metabolites. The fibre-indolepropionate association was partially explained by indolepropionate-associated gut bacteria, mostly fibre-using Firmicutes. We identified a novel association between a host functional LCT variant (determining lactase persistence) and serum indolepropionate, which might be related to a host gene-diet interaction on gut Bifidobacterium, a probiotic bacterium significantly associated with indolepropionate independent of other fibre-related bacteria. Higher milk intake was associated with higher levels of gut Bifidobacterium and serum indolepropionate only among genetically lactase non-persistent individuals. Conclusion Higher milk intake among lactase non-persistent individuals, and higher fibre intake were associated with a favourable profile of circulating tryptophan metabolites for T2D, potentially through the host-microbial cross-talk shifting tryptophan metabolism toward gut microbial indolepropionate production.

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DO - 10.1136/gutjnl-2021-324053

M3 - Article

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AN - SCOPUS:85108505314

SN - 0017-5749

VL - 71

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JO - Gut

JF - Gut

IS - 6

ER -

Host and gut microbial tryptophan metabolism and type 2 diabetes: an integrative analysis of host genetics, diet, gut microbiome and circulating metabolites in cohort studies

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